JP7017237B2 - Track roadbed measurement system - Google Patents

Description

The present invention relates to a roadbed measurement system for tracks, and more specifically, in the work of installing a track slab on roadbed concrete, the position, depth, and range that require checking the condition of the roadbed concrete surface and polishing repair are simplified. It also relates to a track bed measurement system that can be safely identified and thereby significantly reduce the cost and time required for track slab installation work.

In recent years, slab tracks have been used as rail tracks for railway vehicles. As shown in FIG. 9, the slab track is divided into a plurality of units, and each unit is connected in series for each protrusion. Each unit is composed of track slabs of concrete plates, adjusting mortar that fills the gap between the track slabs and roadbed concrete, and protrusions that suppress lateral displacement of the track slabs. In this way, the rail is firmly supported by the slab track, so that it is less likely to be distorted and maintenance is almost unnecessary. Therefore, the slab track is used as a track for laying tracks for high-speed railway vehicles such as the Shinkansen.

The height of the roadbed concrete of the slab track should be adjusted with a predetermined jig so that the builder can pour the concrete into the formwork at the work site and obtain a predetermined gradient (target gradient or design gradient). Made by. Therefore, for the entire surface of the roadbed concrete, the slope is unlikely to be the target slope, and the surface of the roadbed concrete usually exceeds (bulges or swells) or falls below the target slope over a wide area (dented). Yes). On the other hand, the track slab installed on the roadbed concrete is made in advance with high accuracy so as to have the standard dimensions at the factory.

Therefore, when the track slab is installed between the protrusions on the roadbed concrete, in most cases, the track slab does not fit well between the protrusions due to the protrusion (convex portion) on the surface of the roadbed concrete. Therefore, the builder creates an actual size model (hollow wooden frame) that simulates the actual external dimensions of the track slab in advance, temporarily places the actual size model on the roadbed concrete, and depending on the fitting condition, the protruding part of the roadbed concrete surface. The position, depth, and range of are specified. Then, the builder polishes the corresponding position on the roadbed concrete surface so that the actual size model fits between the protrusions.

The actual size model is manufactured in the factory, then transported to the work site by a truck, and then lifted by a lifting machine such as a crane and unloaded from the truck. The actual size model unloaded from the truck is usually carried by six builders to the installation site on the roadbed concrete.

Japanese Unexamined Patent Publication No. 7-209883 Japanese Unexamined Patent Publication No. 2018-9394

In the polishing repair work using the above-mentioned actual size model, the production cost for producing the actual size model and the transportation cost for transporting the actual size model to the work site by truck and unloading the actual size model from the truck are separately incurred. do. In addition, after the polishing repair work is completed, the work of recording the work result (polishing position, depth, range) is separately required. Further, since the actual size model has external dimensions of 2 m in length × 5 m in width × 0.19 m in height, it is necessary to consider safety such as dropping. As described above, the polishing repair work has problems that extra cost and time than usual and safety management are required.

By the way, in Patent Document 2 above, a design straight line (management line) which is a target gradient for a concrete floor board is acquired in advance, the concrete floor board is measured and scanned by a laser ranging device, and the obtained measurement point group is taken into a computer. , A measurement method is disclosed in which the deviation value from the control line of the concrete floor board is measured by a dedicated program inside the computer.

Therefore, in the work of installing the track slab on the roadbed concrete, it can be easily conceived by a person skilled in the art to detect the protruding portion on the surface of the roadbed concrete by using the above measurement method.

However, the actual size model has a horizontal dimension of 5 m. For example, when checking the inclination of the concrete floor board at intervals of 20 cm along the horizontal direction, a total of 25 (= 500/20) management lines are acquired in advance.・ It is necessary to measure. That is, there is a problem that the measurement work is required 25 times and the check work becomes complicated.

Therefore, the present invention has been made in view of the above-mentioned problems of the prior art, and an object of the present invention is that in the work of installing the track slab on the roadbed concrete, it is necessary to check the quality of the roadbed concrete surface and repair it by polishing. It is an object of the present invention to provide a track bed measurement system that can easily and safely specify a position, a depth, and a range, thereby significantly reducing the cost and time required for track slab installation work.

The roadbed measurement system according to the present invention for achieving the above object is a surveying instrument (1) having a distance measuring function and an angle measuring function by light waves, and one or a plurality of creating a reference point of the measurement coordinate system of the surveying instrument. The roadbed measurement for the track, which is composed of the target unit (2, 3) of the above and the computer (4) that processes the data measured by the surveying instrument (1), and measures the roadbed surface (50a) on which the track slab is installed. The system (100) has a design coordinate acquisition process (S1) for preliminarily acquiring a plurality of design coordinates (51, 52, 53, 54) which are target coordinates in the design stage of the roadbed surface (50a), and the design. The target gradient at the design stage of the roadbed surface (50a) is calculated based on the coordinates, and the height (h) from the roadbed surface (50a) in the virtual plane having the target gradient is the depth of the track slab. Using the virtual orbit slab upper surface creation process (S3) for creating the virtual orbit slab upper surface (50b) passing through the known points (40a, 41a) on the measurement coordinate system equal to (D), and the surveying instrument (1). A scan process (S4) that measures the inside of the roadbed surface (50a) at predetermined measurement intervals to acquire a plurality of real coordinates, and a distance (Lm, n) from the real coordinates to the upper surface of the virtual orbit slab (50b). ), And the repair position extraction process (S5 to S7) for extracting the position on the roadbed surface (50a) at which the distance (L) is equal to or less than a predetermined threshold is provided.

In the above configuration, the virtual track slab upper surface (50b) when the track slab is installed on the design roadbed surface (50 "a) as a reference surface for determining the condition (unevenness state) of the roadbed surface (50a). The upper surface of the virtual track slab (50b) is a point on the same measurement coordinate system as the actual roadbed surface (50a) and is the height from the roadbed surface (50a) (50a). h) is preset to pass through a known point (40a, 41a) equal to the depth (D) of the orbital slab. Thereby, by measuring the known point (40a, 41a) once, it is simple. It is possible to measure the elevation difference (= distance L) of the roadbed surface (50a) with respect to the upper surface (50b) of one virtual track slab. That is, on the roadbed surface (50a) by the above scan process (S4). When the actual coordinates (lattice coordinates Pm, n) of are obtained, the elevation difference of the roadbed surface (50a) with respect to the upper surface (50b) of the virtual orbit slab is immediately acquired, and the measurement result of the acquired elevation difference is used as the basis. It is possible to instantly specify the position, depth, and range on the roadbed surface (50a) that needs to be repaired.

The second feature of the present invention is to set the height dimension (h) of the known points (40a, 41a) from the roadbed surface (50a) to a value corresponding to the depth (D) of the track slab. , The height position setting process (S2) used as the reference point of the measurement coordinate system is provided.

In the above configuration, the measurement coordinate system is automatically set by measuring the known points (40a, 41a) by the surveying instrument (1), and the virtual reference plane for the elevation difference of the roadbed surface (50a) is used. The upper surface of the track slab (50b) will be set. As a result, the measurement scan of the roadbed surface (50a) and the altitude of the roadbed surface (50a) with respect to the virtual track slab upper surface (50b) are triggered by the measurement of the known points (40a, 41a) by the surveying instrument (1). It is possible to automatically start the measurement of the difference.

The third feature of the present invention is that the surveying instrument (1) increases the measurement interval as the linear distance (S) from the instrument point (IP) to the measurement point increases in the scan process (S4). It is to measure the roadbed surface (50a).

With the above configuration, it is possible to reduce the measurement error in the scan process (S4) and acquire highly accurate real coordinates (lattice coordinates Pm, n).

A fourth feature of the present invention is that the computer (4) rearranges a plurality of real coordinates acquired in the scan process (S4) in a grid pattern.

In the above configuration, by rearranging the actual coordinates in a grid pattern, it becomes easy to specify the protruding position of the roadbed surface (50a), and further, it becomes easy to specify the depth / range to be polished and repaired.

A fifth feature of the present invention is that the computer (4) emphasizes and displays the position on the roadbed surface (50a) where the distance (Lm, n) is equal to or less than a predetermined threshold value.

With the above configuration, the installer can easily understand the position, depth, and range on the roadbed surface (50a) to be polished and repaired.

According to the track bed measurement system of the present invention, the upper surface (50b) of the virtual track slab, which is the reference plane for the elevation difference of the track surface (50a), is a point on the measurement coordinate system of the surveying instrument (1). The height dimension (h) is preset so as to pass through the known points (40a, 41a) corresponding to the depth dimension (D) of the track slab. As a result, by measuring the known points (40a, 41a) with the surveying instrument (1), the measurement coordinate system is automatically set and the virtual orbit slab upper surface (50b) is set. As a result, the measurement scan of the roadbed surface (50a) and the roadbed surface (50a) with the virtual track slab upper surface (50b) as the reference surface are triggered by the measurement of the known points (40a, 41a) by the surveying instrument (1). It is possible to automatically start the measurement of the elevation difference of. As a result, in the work of installing the track slab on the roadbed concrete, the position, depth, and range that require checking the condition of the roadbed concrete surface and polishing repair are simply and safely specified, and the track slab is installed by this. It is possible to significantly reduce the cost and time required for the work.

It is explanatory drawing which shows the roadbed concrete measurement system for track which concerns on one Embodiment of this invention. It is a flow chart which shows an example of the measurement process by the roadbed concrete measurement system for this track. It is explanatory drawing which shows the design coordinates of the track slab installation surface. It is explanatory drawing which shows the upper surface of the virtual orbit slab which concerns on this invention. It is explanatory drawing which shows the measurement scan with respect to the track slab installation surface which concerns on this invention. It is explanatory drawing which shows the rearrangement to the grid coordinates of the measurement point cloud which concerns on this invention. It is explanatory drawing which shows the distance to the virtual orbit slab about each lattice coordinate of the mth row. It is explanatory drawing which shows the result of having extracted the position which needs repair about the track slab installation surface by the data processing apparatus which concerns on this invention. It is explanatory drawing which shows the slab track for a railroad.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is an explanatory diagram showing a track concrete measuring system 100 for a track according to an embodiment of the present invention.

The track concrete measuring system 100 measures (scans) the track slab installation surface (measured surface) 50a on the track concrete 50 on which the track slab (FIG. 9) is installed at high speed, and the track slab installation surface 50a. Measurement that can check the finished state (concrete state) and add visual information such as color to the position, depth, and range of the track slab installation surface 50a that requires polishing repair when installing the track slab. It is a system. That is, it is possible to extract the position, depth, and range of the track slab installation surface 50a that requires polishing repair from the measurement point group regarding the track slab installation surface 50a acquired by scanning. From the measurement result, the builder can know which position (depth, range) of the track slab installation surface 50a should be polished.

As a configuration, a surveying instrument 1 having a distance measuring function by a light wave and an angle measuring function by an encoder, and a first target unit 2 and a second target unit for creating a measurement reference point that reproduces the same coordinate system (instrument point IP). 3 and a data processing device 4 for processing the measured values measured by the surveying instrument 1 are provided, and the trackbed concrete measuring system 100 is configured. The measurement reference points of the measurement system 100 are the first pin 40a of the first protrusion 40 and the second pin 41a of the second protrusion 41 provided on both sides of the track slab installation surface 50a. The first pin 40a and the second pin 41a are provided inside each of the first protrusion 40 and the second protrusion 41, and the height dimension h from the track slab installation surface 50a is the depth of the track slab (FIG. 9) in advance. It is set to be equal to D.

Further, although the details will be described later, the coordinates of the first pin 40a or the coordinates of the second pin 41a are the virtual track slab upper surface 50b which is a reference plane when measuring the elevation difference (FIG. 7) of the track slab installation surface 50a. It is also the coordinates for determining (FIG. 4). The relative positional relationship between the "coordinates of the first pin 40a" and the "coordinates of the first mirror 2a of the first target unit 2", and the "coordinates of the second pin 41a" and the "second target unit 3". The relative positional relationship with the "coordinates of the second mirror 3a" is known. Therefore, when the builder measures (collimates) the first mirror 2a and the second mirror 3a, the measurement coordinate system (instrument point IP) of the surveying instrument 1 is determined, and the elevation difference of the track slab installation surface 50a is determined. The virtual orbital slab upper surface 50b (FIG. 4), which is the reference plane for measuring (FIG. 7), will be determined. As a result, the roadbed concrete measurement system 100 for this track is always in a measurable state (measurement standby state). Hereinafter, each configuration will be described in more detail.

In addition to the distance measuring function and the angle measuring function, the surveying instrument 1 can measure a three-dimensional surface (outer surface of a structure) at a predetermined measurement interval (point density) at high speed without a mirror (non-prism). It has a 3D scanner function. The measurement coordinate system of the surveying instrument 1 is determined by the backward interaction method, for example, by collimating the first mirror 2a of the first target unit 2 and the second mirror 3a of the second target unit 3. Is the instrument point IP, the north direction (hereinafter referred to as "N axis") is one reference axis on the track slab installation surface 50a, and the east direction (hereinafter referred to as "E axis") is the other on the track slab installation surface 50a. The reference axis can be the vertical direction (hereinafter referred to as “H axis”) passing through the instrument point IP of the surveying instrument 1 as the reference axis in the height direction.

The data processing device 4 has a two-way wireless communication function, receives coordinate data related to a group of measurement points obtained by scanning with a surveying instrument 1 wirelessly, rearranges them in a mesh shape, and installs an orbital slab. It is possible to add visual information such as color to the measurement result related to the elevation difference of the surface 50a and display it on the monitor screen. It is also possible to output the screen displayed at the same time to a printing machine (printer).

As described above, in the track concrete measuring system 100 for the track, the surveying instrument 1 can always measure the track 1 pin 40a and the second pin 41a, and the elevation difference of the track slab installation surface 50a (FIG. 7) can be obtained. Only the virtual orbital slab upper surface 50b (FIG. 4) is sufficient as the reference plane for measurement. Hereinafter, the measurement process by the roadbed concrete measurement system 100 for this track will be described.

FIG. 2 is a flow chart showing an example of a measurement process by the roadbed concrete measurement system 100 for this track.
First, as step S1, the design coordinates for the track slab installation surface 50a are acquired. The design coordinates are coordinates (FIG. 3) on the track slab installation surface (hereinafter referred to as "design track slab installation surface") 50 "a having a target gradient (construction target value) at the design stage. Using these design coordinates, the target slope of the design track slab installation surface 50 "a can be calculated.

As shown in FIG. 3, as the design coordinates selected, the design coordinates of four points located on both sides of the central axis CL between the first pin 40a and the second pin 41a and located closer to each pin. It is desirable to obtain 51,52,53,54. The coordinates 51, 52, 53, 54 can be obtained from, for example, a designer of the roadbed concrete 50.

Next, as step S2, the height and position of the first pin 40a and the second pin 41a are measured. As described above, the coordinates of the first pin 40a or the second pin 41a determine the virtual track slab upper surface 50b (FIG. 4) which is the reference plane for measuring the elevation difference (FIG. 7) of the track slab installation surface 50a. It becomes the coordinates for. Therefore, the height h of the first pin 40a or the second pin 41a is preset so as to be equal to the depth D of the track slab (FIG. 9) at the site. In general, the equation of a plane is determined by a gradient (normal vector) and one passing point. Therefore, as the passing point for determining the virtual orbit slab upper surface 50b (FIG. 4), the coordinates of the first pin 40a are used here. Therefore, as for the height setting of the pin, it is sufficient to set the height dimension h of the first pin 40a.

Next, as step S3, the virtual orbit slab upper surface 50b is created. As shown in FIG. 4A, the virtual track slab upper surface 50b corresponds to the track slab upper surface when the actual track slab (FIG. 9) is placed on the design track slab installation surface 50 "a. The virtual track slab upper surface 50b means a virtual plane created by the target gradient of the design track slab installation surface 50 "a and the measurement reference point (first pin 40a or second pin 41a). The target gradient is calculated based on the design coordinates 51, 52, 53, 54 in step S1, and the coordinates of the first pin 40a are used as the passing points for determining the plane in this embodiment. It is also possible to use the coordinates of the second pin 41a as the passing point.

Therefore, as shown in FIG. 4B, by replacing the design track slab installation surface 50 "a with the actual track slab installation surface 50a, the elevation difference of the track slab installation surface 50 from the virtual track slab upper surface 50b ( It is possible to instantly identify the position, depth, and range (that is, the portion requiring polishing repair) of the track slab installation surface 50a (roadbed concrete 50) in which FIG. 7) is equal to or less than a predetermined threshold.

Next, as step S4, the track slab installation surface 50a is scanned using the surveying instrument 1. As shown in FIG. 5B, the surveying instrument 1 automatically calculates the minimum scan range 50c surrounding the track slab installation surface 50a based on the coordinates of the first pin 40a and the coordinates of the second pin 41a. And start scanning. At that time, as shown in FIG. 5A, regarding the density of the measurement point group, the surveying instrument increases the density of the measurement point group as the linear distance S from the instrument point IP to the measurement point becomes longer. 1 scans the scan range 50c.

Next, as step S5, the measurement point cloud acquired by the scan in step S4 is rearranged on the mesh (lattice). As shown in FIG. 6, in order to rearrange the scan measurement point group 50d for the track slab installation surface 50a into the mesh measurement point group 50e, for example, the track slab installation surface 50a is placed at a predetermined interval parallel to the central axis CL. 16 × 36 = 576 rectangular cells are formed by dividing into 16 cells at predetermined intervals parallel to the straight line L orthogonal to the central axis CL. Then, by using the average value of each coordinate of all the measurement points belonging to each cell as the representative coordinate value of the cell, the scan measurement point group 50d can be rearranged in the mesh measurement point group 50e. Therefore, in the present embodiment, representative coordinate values (hereinafter referred to as “lattice coordinates”) relating to 576 Cartesian coordinate systems are generated.

Next, as step S6, the distances Lm and n to the virtual orbit slab upper surface 50b of each lattice coordinate are calculated. FIG. 7 shows the calculation of the distances Lm and n for each lattice coordinate in the mth row. The distances Lm and n are values corresponding to the elevation difference of the track slab installation surface 50a with the virtual slab upper surface 50b as the reference surface. The distances Lm and n are easily calculated by the equations of the lattice coordinates (N, E, H) and the plane of the virtual orbit slab upper surface 50b.

Next, as step S7, the position, depth, and range of the track slab installation surface 50a that requires polishing repair are specified. As shown in FIG. 8, the distance Lm, n (m = 1, ..., 16, n = 1, ..., 36) calculated by step S7 and the depth of the actual orbital slab (FIG. 9). With respect to the difference value (= Lm, n−D) from the D, the negative lattice coordinates Pm, n are extracted. The positions where polishing repair is required can be specified by the extracted lattice coordinates Pm and n, and the required polishing amount can be specified by the magnitude (absolute value) of the difference value. Further, since each lattice coordinate Pm, n has a cell area, it is possible to specify the area to be cut. Further, when extracting, the cells of each lattice coordinate can be colored according to the magnitude (absolute value) of the difference value.

As described above, according to the track concrete measurement system 100 for tracks of the present invention, the virtual track slab upper surface 50b, which is the reference surface for the elevation difference of the track surface 50a, is the reference point on the measurement coordinate system of the surveying instrument 1. It is preset so as to pass through the coordinates of the first pin 40a or the coordinates of the second pin 41a. The height dimension h from the roadbed surface 50a of the first pin 40a is set in advance so as to be equal to the depth D of the track slab. As a result, the measurement coordinate system is automatically set by measuring the first pin 40a and the second pin 41a by the surveying instrument 1, and the virtual track slab upper surface 50b which is the reference plane of the elevation difference of the roadbed surface 50a. Will be set. As a result, the measurement scan of the roadbed surface 50a and the measurement of the elevation difference from the virtual track slab upper surface 50b of the roadbed surface 50a are automatically started by the measurement of the first pin 40a and the second pin 41a by the surveying instrument 1. It becomes possible to do. As a result, in the work of installing the track slab on the roadbed concrete 50, the position, depth, and range where the track slab installation surface 50a needs to be checked and polished and repaired are simply and safely specified. It is possible to significantly reduce the cost and time required for track slab installation work.

1 Surveying instrument 2 1st target unit 2a 1st mirror 3 2nd target unit 2b 2nd mirror 3 target unit 4 Data processing device (computer)
40 1st protrusion 40a 1st pin 41 2nd protrusion 41a 2nd pin 50 Roadbed concrete 50a Track slab installation surface (roadbed surface)
50 "a Design track slab installation surface 50b Virtual track slab upper surface 50c Scan range 50d Scan measurement point cloud for track slab installation surface 50a Mesh measurement point cloud for track slab installation surface 50a 100 Track concrete measurement system

Claims (5)

A surveying instrument (1) having a distance measuring function and an angle measuring function by light waves, one or a plurality of target portions (2, 3) for creating reference points (40a, 41a) in the measurement coordinate system of the surveying instrument, and the above. It is an orbital roadbed measurement system (100) that measures the roadbed surface (50a) on which the orbital slab is installed, which is composed of a computer (4) that processes the data measured by the surveying instrument (1).
A design coordinate acquisition process (S1) for preliminarily acquiring a plurality of design coordinates (51, 52, 53, 54) which are target coordinates in the design stage of the roadbed surface (50a).
The target gradient at the design stage of the roadbed surface (50a) is calculated based on the design coordinates, and the height (h) from the roadbed surface (50a) in the virtual plane having the target gradient is the track slab. A virtual orbit slab top surface creation process (S3) for creating a virtual orbit slab top surface (50b) that passes through known points (40a, 41a) on the measurement coordinate system equal to the depth (D).
A scanning process (S4) in which the inside of the roadbed surface (50a) is measured at predetermined measurement intervals using the surveying instrument (1) and a plurality of real coordinates are acquired.
Repair to calculate the distance (Lm, n) to reach the upper surface of the virtual track slab (50b) from the actual coordinates and extract the position on the roadbed surface (50a) where the distance (L) is equal to or less than a predetermined threshold value. Position extraction process (S5 to S7) and
A roadbed measurement system for tracks, which is characterized by being equipped with. In the track bed measurement system according to claim 1,
The height dimension (h) of the known points (40a, 41a) from the roadbed surface (50a) is set to a value corresponding to the depth (D) of the track slab, and the reference point of the measurement coordinate system is set. A track bed measurement system characterized by being equipped with a height position setting process (S2). In the track bed measurement system according to claim 1 or 2.
The surveying instrument (1) measures the roadbed surface (50a) by increasing the measurement interval as the linear distance (S) from the instrument point (IP) to the measurement point increases in the scan process (S4). A roadbed measurement system for tracks, which is characterized by this. In the track roadbed measurement system according to any one of claims 1 to 3,
The computer (4) is an orbital roadbed measurement system characterized by rearranging a plurality of real coordinates acquired in the scan process (S4) in a grid pattern. In the track roadbed measurement system according to any one of claims 1 to 4.
The computer (4) is an orbital roadbed measuring system characterized in that the position on the roadbed surface (50a) where the distance (Lm, n) is equal to or less than a predetermined threshold value is emphasized and displayed.

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